Preparation of functional styrenes from biosourced carboxylic acids by copper catalyzed decarboxylation in PEG

Cadot, Stéphane; Rameau, Nelly; Mangematin, Stéphane; Pinel, Catherine; Djakovitch, Laurent

doi:10.1039/c4gc00256c

Cited by 39 publications

(49 citation statements)

References 52 publications

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“…These results suggest that the o ‐ and p ‐hydroxy groups work efficiently for the simple base‐induced decarboxylation of cinnamic acids due to the resonance effects. However, decarboxylation of m ‐coumaric acid into m ‐hydroxystyrene (3VP) was successfully achieved by the other common method using a copper catalyst …”

Section: Resultsmentioning

confidence: 99%

Bio‐based vinylphenol family: Synthesis via decarboxylation of naturally occurring cinnamic acids and living radical polymerization for functionalized polystyrenes

Takeshima

Satoh

Kamigaito

2019

Journal of Polymer Science

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A series of bio‐based vinylphenols or hydroxystyrenes is prepared by simple decarboxylation of various naturally occurring cinnamic acids such as o‐, m‐, and p‐coumaric; caffeic; ferulic; and sinapinic acids, which possess hydroxy groups and other substituents at different positions on the aromatic ring. After protection of the phenolic moieties with trialkylsilyl groups, reversible addition–fragmentation chain‐transfer polymerization is accomplished with cumyl dithiobenzoate to afford various bio‐based hydroxyl‐protected polystyrenes with controlled molecular weights and narrow molecular weight distributions. Subsequent deprotection of the silyl groups under mild conditions results in a series of well‐defined functionalized polystyrenes possessing different numbers (mono‐, di‐, tri‐) of hydroxy groups at different positions (o, m, p). The obtained functionalized polystyrenes show unique thermal properties depending on the substituents, and those with phenol and catechol groups serve as reducing agents for silver ions. © 2019 Wiley Periodicals, Inc. J. Polym. Sci. 2020, 58, 91–100

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Section: Resultsmentioning

confidence: 99%

Bio‐based vinylphenol family: Synthesis via decarboxylation of naturally occurring cinnamic acids and living radical polymerization for functionalized polystyrenes

Takeshima

Satoh

Kamigaito

2019

Journal of Polymer Science

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“…However, acetophenone itself was partially consumed by transamination to 1phenethylamine (entry 25). α,β-Unsaturated ketones (entries [14][15][16][17][18][19][20][21][22][23][24], in particular the derivatives of 2-cyclohexen-1-one (entries 18-21 and 23), are among the most active organocatalysts: for instance, 2 a was produced in > 85 % yield within 4 h by using isophorone or 3-phenyl-2-cyclohexen-1-one. These catalysts increased the amine yield at least by a factor 10 compared to the thermal reaction.…”

Section: Decarboxylation Of Amino Acids To Aminesmentioning

confidence: 99%

“…The non‐oxidative decarboxylation of amino acids is catalysed by homogeneous transition metal complexes, such as Cu I ‐phenanthroline . However, this method involves high catalyst loadings (10 mol%) and proceeds at high temperature (>180 °C).…”

Section: Introductionmentioning

confidence: 99%

“…[15,16] The non-oxidative decarboxylation of amino acids is catalysed by homogeneous transition metal complexes, such as Cu Iphenanthroline. [17] However, this method involves high catalyst loadings (10 mol%) and proceeds at high temperature (> 180°C). Moreover, the scope is limited to amino acids with aliphatic and aromatic side chains, from which the corresponding primary amines are isolated only in moderate yield (up to 68 %).…”

Section: Introductionmentioning

confidence: 99%

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Organocatalytic Decarboxylation of Amino Acids as a Route to Bio‐based Amines and Amides

2019

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Amino acids obtained by fermentation or recovered from protein waste hydrolysates represent an excellent renewable resource for the production of bio‐based chemicals. In an attempt to recycle both carbon and nitrogen, we report here on a chemocatalytic, metal‐free approach for decarboxylation of amino acids, thereby providing a direct access to primary amines. In the presence of a carbonyl compound the amino acid is temporarily trapped into a Schiff base, from which the elimination of CO2 may proceed more easily. After evaluating different types of aldehydes and ketones on their activity at low catalyst loadings (≤5 mol%), isophorone was identified as powerful organocatalyst under mild conditions. After optimisation many amino acids with a neutral side chain were converted in 28–99 % yield in 2‐propanol at 150 °C. When the reaction is performed in DMF, the amine is susceptible to N‐formylation. This consecutive reaction is catalysed by the acidity of the amino acid reactant itself. In this way, many amino acids were efficiently transformed to the corresponding formamides in a one‐pot catalytic system.

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“…Random stereo‐irregular copolymers of styrene (S) with 1,3‐butadiene (B) (styrene–butadiene–rubber) are by far the most commercially important commodity polymers of these monomers, produced in amounts of the order of 5.3 million tons in 2014 via emulsion or solution processes; these copolymers find applications as adhesives and sealants, and in gasket and tyre production . To face environmental concerns and make their production more sustainable, the drop‐in synthesis of B and S is emerging to satisfy the increasing demand for these monomers and to replace the petrochemical/natural feedstocks with renewable sources. More interestingly diblock copolymers of S with B and high‐impact polystyrene can produce micro‐ and nanophase separated morphologies where the glassy polystyrene (PS) acts as a reversible physical crosslink in the flexible rubber phase of poly(1,3‐butadiene) (PB) .…”

Section: Introductionmentioning

confidence: 99%

Thin‐film nanostructure and polymer architecture in semicrystalline syndiotactic poly(p‐methylstyrene)–(cis‐1,4‐polybutadiene) multiblock copolymers

Buonerba

Monica

Speranza

et al. 2019

Polymer International

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The thin‐film morphology of stereoregular syndiotactic poly(p‐methylstyrene)–(cis‐1,4‐polybutadiene) (sP(pMS–B)) multiblock copolymers has been investigated using tapping mode atomic force microscopy with variation of the polymer composition and monomer block lengths. The morphology of the thin films ranges from isolated circular domains of sP(pMS) embedded into a matrix of polybutadiene (PB) to isolated domains of PB embedded into a matrix of sP(pMS), passing through bicontinuous (jagged) lamellae when the pMS concentration is in the range 20–67 mol%. Multiple folding of the polymer segments, i.e. where reciprocal inclusions of polymer segments to each other phase are able to generate greater domain, has been postulated and validated by considerations on the polymer architecture and the thermal and crystalline behaviour. © 2019 Society of Chemical Industry

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Preparation of functional styrenes from biosourced carboxylic acids by copper catalyzed decarboxylation in PEG

Cited by 39 publications

References 52 publications

Bio‐based vinylphenol family: Synthesis via decarboxylation of naturally occurring cinnamic acids and living radical polymerization for functionalized polystyrenes

Bio‐based vinylphenol family: Synthesis via decarboxylation of naturally occurring cinnamic acids and living radical polymerization for functionalized polystyrenes

Organocatalytic Decarboxylation of Amino Acids as a Route to Bio‐based Amines and Amides

Thin‐film nanostructure and polymer architecture in semicrystalline syndiotactic poly(p‐methylstyrene)–(cis‐1,4‐polybutadiene) multiblock copolymers

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